The present invention provides an apparatus and an associated method for sampling timing compensation, which can estimate sampling frequency offset between the receiver and transmitter of a multi-carrier system according to estimated frequency responses of two consecutive received symbols within each pilot subchannel, and compensate an accumulated sampling timing offset resulted from the sampling frequency offset. When the accumulated timing offset is not large, the apparatus uses a phase rotator to compensate with a corresponding accumulated phase rotation in frequency domain. When the accumulated timing offset is large, the apparatus first compensates with a specific timing offset in time domain, and then uses the phase rotator to compensate with a phase rotation corresponding to the remaining timing offset in frequency domain. A timing controller is used to compensate with the specific timing offset by adjusting a clock generator or a cyclic prefix remover of the receiver.
Legal claims defining the scope of protection, as filed with the USPTO.
1. An apparatus for sampling timing compensation at a receiver of a communication system, wherein each of a first and a second symbol signals comprises two pilot signals transmitted via a first and a second pilot subchannels respectively, and the first and the second pilot subchannels comprise a first and a second pilot indexes respectively, the apparatus comprising: a pilot subchannel estimator for generating first frequency responses of two of the pilot signals transmitted over the first pilot subchannel and generating second frequency responses of the other two of the pilot signals transmitted over the second pilot subchannel; a timing offset estimator, coupled to the pilot subchannel estimator, for calculating a timing offset according to a first difference between the first frequency responses of the first and second symbol signals, a second difference between the second frequency responses of the first and second symbol signals and a subtraction between the first and second differences; and a phase rotator, coupled to the timing offset estimator, for performing sampling timing compensation according to a phase rotation corresponding to the timing offset.
2. The apparatus of claim 1 , wherein the communication system is a multi-carrier system.
3. The apparatus of claim 1 , wherein the timing offset estimator further comprises a phase difference calculating device for calculating the first difference and the second difference, and a divider for calculating the timing offset according to the subtraction between the first and second differences and the first and the second pilot indexes.
4. The apparatus of claim 1 , further comprising: a timing controller for generating a control signal according to the timing offset; a clock generator for generating a sampling clock according to the control signal, wherein the phase of the sampling clock is adjusted according to the control signal; and an analog-to-digital converter (ADC) for converting the symbol signals according to the sampling clock.
5. The apparatus of claim 4 , wherein a period of the sampling clock (T f ) is shorter than a sampling interval (Ts) of the ADC.
6. The apparatus of claim 5 , wherein the period of the sampling clock (T f ) is a fraction of the sampling interval (T s ) of the ADC.
7. The apparatus of claim 4 , wherein the clock generator further comprises a phase-locked loop (PLL) circuit.
8. A method for sampling timing compensation at a receiver of a communication system, wherein each of a first and a second symbol signals comprises two pilot signals transmitted via a first and a second pilot subchannels respectively, and the first and the second pilot subchannels comprise a first and a second pilot indexes respectively, the method comprising: generating first frequency responses of two of the pilot signals transmitted over the first pilot subchannel; generating second frequency responses of the other two of the pilot signals transmitted over the second pilot subchannel; generating a first difference between the first frequency responses of the first and second symbol signals; generating a second difference between the second frequency responses of the first and second symbol signals; calculating a timing offset according to a subtraction between the first and the second differences; and performing sampling timing compensation according to a phase rotation corresponding to the timing offset.
9. The method of claim 8 , wherein the timing offset is calculated according to the subtraction between the first and second differences and the first and the second pilot indexes.
10. The method of claim 8 , further comprising: generating a control signal according to the timing offset; and generating a sampling clock according to the control signal, wherein a phase of the sampling clock is adjusted according to the control signal.
11. An apparatus for sampling timing compensation at a receiver of a communication system, wherein each of a first and a second symbol signals comprises transmitted via a first a second pilot subchannels respectively, and the first and the second pilot subchannels comprise a first and a second pilot indexes respectively, the apparatus comprising: a pre-FFT processing device for processing the first and the second symbol signals in a time domain; a FFT for transforming the first and the second symbol signals from the time domain to a frequency domain; a pilot subchannel estimator for generating first frequency responses of two of the pilot signals transmitted over the first pilot subchannel and generating second frequency responses of the other two of the pilot signals transmitted over the second pilot subchannel; a timing offset estimator, coupled to the pilot subchannel estimator, for calculating a timing offset according to a first difference between the first frequency responses of the first and second symbol signals, a second difference between the second frequency responses of the first and second symbol signals and a subtraction between the first and second differences; a phase rotator, coupled to the timing offset estimator, for performing sampling timing compensation according to a phase rotation corresponding to the timing offset; and a adjusting device for adjusting the operation of the pre-FFT processing device.
12. The method of claim 11 , wherein the pre-FFT processing device includes an ADC.
13. The method of claim 12 , wherein the adjusting device includes: a timing controller for generating a control signal according to the timing offset; and a clock generator for generating a sampling clock according to the control signal for controlling the operation of the ADC, wherein the phase of the sampling clock is adjusted according to the control signal.
14. An method for sampling timing compensation at a receiver of a communication system, wherein each of a first and a second symbol signals comprises two pilot signals transmitted via a first and a second pilot subchannels respectively, and the first and the second pilot subchannels comprise a first and a second pilot indexes respectively, the method comprising: processing the first and the second symbol signals in a time domain; transforming the first and the second symbol signals from the time domain to a frequency domain; generating first frequency responses of two of the pilot signals transmitted over the first pilot subchannel; generating second frequency responses of the other two of the pilot signals transmitted over the second pilot subchannel; generating a first difference between the first frequency responses of the first and second symbol signals; generating a second difference between the second frequency responses of the first and second symbol signals; calculating a timing offset according to a subtraction between the first and second differences; performing sampling timing compensation according to a phase rotation corresponding to the timing offset; and adjusting the operation of the step of processing symbol signals in the time domain.
Cooperative Patent Classification codes for this invention. Click any code to explore related patents in that topic.
March 18, 2004
March 16, 2010
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